How Science Builds Knowledge
No scientist works completely alone. Barry Marshall and Robin Warren in Perth had an idea that a bacterium caused stomach ulcers, but their idea only became accepted knowledge after many other laboratories around the world repeated the work and got the same results. Science is a team effort that builds up over time. In this lesson you will see how scientists build on each other's work, and how repeated tests turn an idea into a trusted theory or law.
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Q1 · A scientist makes a brand new discovery, but no other scientist has checked it yet. Do you think the world should fully trust it straight away? Why or why not?
Q2 · You have probably heard the word "theory" used to mean a wild guess, like "that is just a theory". Do you think a scientific theory is the same as a guess? Explain what you think a scientific theory is.
● Know
- Scientific research is usually collaborative and builds on the work of others (NESA SC4-OTU-01, SC4-WS-08)
- Scientific theories and laws are based on repeated experiments and observations (NESA SC4-OTU-01)
- The difference between a hypothesis, a scientific theory and a scientific law
● Understand
- Why one result on its own is not yet trusted knowledge, and why repeating tests matters
- How peer review and replication help check whether an idea is reliable
- How scientists across the world, including teams at the CSIRO, build on each other's work
● Can do
- Explain why science is collaborative and builds on earlier work, using an example
- Put a hypothesis, a theory and a law in order of how much evidence each one has behind it
- Describe in your own words how repeated testing turns an idea into accepted knowledge
Films often show one lonely genius shouting "I've got it!" in a lab. Real science is almost never like that. The NSW syllabus puts it plainly: scientific research is usually collaborative and builds on the work of others. Collaborative means people work together. Building on the work of others means every new discovery stands on top of discoveries made by scientists before.
Here is what that looks like in real life.
- Scientists read what others have already found out, so they do not have to start from zero each time.
- They work in teams, often with people who have different skills, in different countries.
- They share their results so others can use them, check them and build on them.
A great Australian example is the CSIRO, our national science agency. CSIRO teams of many scientists worked together for years to develop fast wireless internet, which is now used all over the world. No single person could have done it alone. Big modern achievements, such as vaccines that protect millions of people, are built by huge international teams sharing their work step by step.
Knowledge in science grows like a tower of building blocks. Each scientist adds a block on top of the blocks placed by earlier scientists. You do not knock the tower down and start again every time; you build higher.
Think about the radio telescope at Parkes in New South Wales, nicknamed Murriyang. It can listen to faint signals from deep space. The scientists who built it used ideas about radio waves and electricity worked out by many earlier scientists. Today, astronomers from all over the world book time on it and share what they find, so the next team can go further again.
This is why scientists publish their work. When a team writes up its results, other scientists can:
- Learn from it, so they do not repeat work that is already done.
- Check it, by repeating the experiment to see if they get the same result.
- Extend it, by asking a new question that the first work made possible.
So a discovery is rarely the end of a story. It is usually a new block that helps the next group of scientists build something even taller.
Scientific research is usually ___, which means scientists work together. New discoveries usually build on the ___ of others. Scientists ___ their results so that other teams can learn from them, check them and build on them.
People often mix up three important science words. The difference is mostly about how much evidence stands behind each one.
- Hypothesis: a testable idea or prediction that you have not checked yet. It is a careful suggestion, such as "warmer water makes coral go pale". A hypothesis is the starting point, not the finish line.
- Scientific theory: a well tested explanation for how something works, backed by lots of evidence from many experiments and observations. A theory is not a wild guess. In everyday speech "theory" can mean a hunch, but in science a theory is one of the strongest things we have, because it has survived years of testing.
- Scientific law: a statement, often short, that describes a pattern that has been observed to happen again and again. For example, things always fall down towards the Earth when dropped. A law describes what happens; a theory explains why it happens.
The big idea from the syllabus is this: scientific theories and laws are based on repeated experiments and observations. They earn our trust because they have been tested over and over by many different people, and they keep holding up.
- Hypothesis
- Scientific theory
- Scientific law
- Collaborative
- A testable idea or prediction that has not been checked yet
- A well tested explanation backed by lots of evidence
- A statement describing a pattern seen again and again
- Working together with other people
How does an idea earn enough trust to become a theory or law? The answer is repeated testing by many people. Two important steps make this happen.
- Peer review: before a result is shared widely, other expert scientists, called peers, read it carefully and check it for mistakes. A peer is a fellow expert, like a teammate who checks your work before you hand it in. If the work is not good enough, they say so, and it has to be fixed.
- Replication: other scientists repeat the experiment themselves to see if they get the same result. If many separate teams keep getting the same result, the idea becomes much more trustworthy. If they cannot repeat it, scientists become doubtful.
Think back to Barry Marshall and Robin Warren in Perth. When they first said a bacterium caused stomach ulcers, most doctors did not believe them. Their idea only became accepted after laboratories around the world repeated the work and kept getting the same result. The repeated experiments and observations turned a doubted idea into trusted medical knowledge, and in 2005 the two scientists won the Nobel Prize.
Because science is built up over time, our knowledge can keep getting better. If new evidence appears that does not fit, scientists update the idea, or sometimes replace it with a better one. This is a strength of science, not a weakness.
- A theory that has passed thousands of tests is very trustworthy, but it is still open to checking.
- If careful new evidence ever disagrees, scientists take that seriously and look again.
- Each improvement still builds on the work that came before. We rarely throw everything away.
For example, telescopes like Murriyang at Parkes and newer space telescopes keep giving us fresh observations of the Universe. Each new set of data lets scientists improve their explanations of how stars and galaxies work. The knowledge grows because thousands of scientists, over many years, keep observing, testing and building on each other's work. That is exactly how science builds reliable knowledge.
In the 1980s, Barry Marshall and Robin Warren claimed a bacterium caused stomach ulcers, but almost no doctor believed them at first. Their idea was just a hypothesis at that point. Predict: what would need to happen, by other scientists around the world, before this idea could become trusted medical knowledge?
How close was your prediction?
At the start of the lesson you wrote whether a brand new, unchecked discovery should be trusted, and what you thought a theory was. Now write an improved, complete answer.
Your answer must: (1) explain why science is collaborative and builds on the work of others; (2) explain why one unchecked result is not yet trusted knowledge; (3) explain how repeated experiments and observations turn an idea into a theory or law. Use the words collaborative, replication, theory and evidence.
Q1. Explain why scientific research is described as collaborative and as building on the work of others. Give one Australian example. (3 marks)
Q2. Put these in order from least to most evidence: scientific law, hypothesis, scientific theory. Write one sentence explaining what each one is. (3 marks)
Q3. A student says "If I get one good result in an experiment, that proves my idea is true straight away." Explain why this is not how science works, using the words repeated and replication. (4 marks)
Answers
▾MCQ 1
B. The syllabus says scientific research is usually collaborative and builds on the work of others. It is not done in secret, it is not based on opinion, and it is not finished forever after one result.
MCQ 2
C. Replication means other scientists repeat an experiment to see if they get the same result. Hiding results, changing data, and believing clever sounding claims are not replication.
MCQ 3
D. A scientific theory is a well tested explanation backed by lots of evidence from many experiments and observations. It is not a wild guess, an untestable opinion, or an idea tested only once.
MCQ 4
A. The idea became accepted because many laboratories around the world repeated the work and kept getting the same result. Secrecy, celebrity claims, and refusing checks are the opposite of how science works.
MCQ 5
C. Peer review is when other expert scientists check the work for mistakes before it is shared widely. It is not about fame, secrecy, or popularity.
Short Answer 1
Model answer: Scientific research is collaborative because scientists work together in teams, often with people who have different skills, and they share their results. It builds on the work of others because each new discovery uses ideas worked out by earlier scientists, instead of starting from zero. For example, CSIRO teams worked together for years to develop fast wireless internet, building on earlier work about radio waves.
Short Answer 2
Model answer: From least to most evidence the order is: hypothesis, scientific theory, scientific law. A hypothesis is a testable idea or prediction that has not been checked yet. A scientific theory is a well tested explanation backed by lots of evidence from many experiments. A scientific law is a statement that describes a pattern seen again and again, such as objects falling towards the Earth when dropped.
Short Answer 3
Model answer: One good result is not enough because it could be a mistake, luck, or a one off. Through replication, other scientists repeat the experiment to see if they get the same result. Only when repeated experiments and observations by many different people keep giving the same result does the idea become trusted knowledge. This is why one result is a starting point, not proof on its own.